Pesticides are viewed as a major wellspring of ecological contamination and causing serious risky consequences for people and animals. Imidacloprid (IM) and hexaflumuron (HFM) are extensively utilized insect poisons for crop assurance on the planet. A few investigations examined IM harmfulness in rodents, but its exact mechanism hasn’t been mentioned previously as well as the toxicity of HFM doesn’t elucidate yet. For this reason, the present study was designed to explore the mechanism of each IM and HFM–evoked rat liver and kidney toxicity and to understand its molecular mechanism. 21 male Wistar albino rats were divided into 3 groups, as follows: group (1), normal saline; group (2), IM; and group (3), HFM. Both insecticides were orally administered every day for 28 days at a dose equal to 1/10 LD50 from the active ingredient. After 28 days postdosing, rats were anesthetized to collect blood samples then euthanized to collect liver and kidney tissue specimens. The results showed marked changes in walking, body tension, alertness, and head movement with a significant reduction in rats’ body weight in both IM and HFM receiving groups. Significant increases in MDA levels and decrease of GHS levels were recorded in liver and kidney homogenates of either IM or HFM groups. Liver and kidney tissues obtained from both pesticide receiving groups showed extensive histopathological alterations with a significant increase in the serum levels of ALT, AST, urea, and creatinine and a decrease in total proteins, albumin, and globulin levels. In addition, there was upregulation of the transcript levels of casp-3, JNK, and HO-1 genes with strong immunopositivity of casp-3, TNF-ὰ, and NF-KB protein expressions in the liver and kidneys of rats receiving either IM or HFM compared with the control group. In all studied parameters, HFM caused hepatorenal toxicity more than those induced by IM. We can conclude that each IM and HFM provoked liver and kidneys damage through overproduction of ROS, activation of NF-KB signaling pathways and mitochondrial/JNK-dependent apoptosis pathway.
Pesticides are widely used in agriculture to kill pests, but their action is non-selective and results in several hazardous effects on humans and animals. Pesticide toxicity has been demonstrated to alter a variety of neurological functions and predisposes to various neurodegenerative diseases. Although, there is no data available for hexaflumuron (HFM) and hymexazol (HML) neurotoxicity. Hence, the present study aims to investigate the possible mechanisms of HFM and HML neurotoxicity. 21 male Wistar rats were divided into three groups and daily received the treatment via oral gavage for 14 days as follows: group (1) normal saline, group (2) HFM (1/100LD50), and group (3) HML (1/100 LD50). Our results revealed that both HFM and HML produced a significant increase in MDA levels and a decrease in GSH and CAT activity in some brain areas. There were severe histopathological alterations mainly neuronal necrosis and gliosis in different examined areas. Upregulation of mRNA levels of JNK and Bax with downregulation of Bcl-2 was also recorded in both pesticides exposed groups. In all studied toxicological parameters, HML produced neurotoxicity more than HFM. HFM targets the cerebral cortex and striatum, while HML targets the cerebral cortex, striatum, hippocampus, and cerebellum. We can conclude that both HFM and HML provoke neurobehavioral toxicity through oxidative stress that impairs the mitochondrial function and activates the JNK-dependent apoptosis pathway.
Hymexazol (HML) is widely used in agriculture as a systemic fungicide and plant growth promoter. Humans are continuously exposed to HML via various routes. The liver and kidneys are essential organs for the detoxification, metabolism, and excretion of HML. However, data concerning the impact of HML on nontarget organisms are scarce. The present study aimed to determine the mechanism of dose‐dependent hepatorenal toxicity of HML in rats. Twenty‐one rats were divided into three equal groups that received the following treatments via oral intake daily for 14 days: group 1, normal saline; group 2, low dose of HML (1/80 LD50); group 3, high dose of HML (1/40 LD50). We weighed the rats at the beginning and the end of the experiment to record the weight gain in each group. The results showed that HML induced dose‐dependent hepatorenal toxicity manifested by a significant increase in malondialdehyde levels, a decrease in total antioxidant capacity and reduced glutathione contents, and upregulation of the transcriptase levels of the nuclear factor kappa B (NF‐κB), tumor necrosis factor alpha (TNF‐α), and interleukin‐1 beta (IL‐1β) genes. The HML‐exposed groups displayed various histopathological changes in both organs, with significant elevation of all serum liver and kidney biomarkers. In conclusion, HML produced hepatorenal toxicity in rats through oxidative stress that mediates the NF‐κB signaling pathway in response to pro‐inflammatory cytokines such as TNF‐α and IL‐1β. We advise limiting the use of HML in agricultural and veterinary practices and finding an alternative agent to avoid the human and animal health risks induced by HML exposure.
Carbendazim (CBZ) is a common environmental pollutant that can contaminate food and water and severely damage human health. Some studies revealed the adverse effect of CBZ on different organs, but its detailed toxicity mechanism has not been elucidated yet. Thus, the present study aims to clarify the mechanisms of CBZinduced hepatorenal toxicity in rats. Therefore, we partitioned 40 male Wistar rats into four groups (n = 10): a negative control group and three treatment groups, which received 100, 300, and 600 mg/kg of CBZ. All rats received the treatment daily by oral gavage. We collected blood and organ samples (liver and kidney) at 14 and 28 days postdosing. CBZ caused extensive pathological alterations in both the liver and kidneys, such as cellular degeneration and necrosis accompanied by severe inflammatory reactions in a dose-and time-dependent manner. All the CBZ-treated groups displayed strong tumor necrosis factor-α and nuclear factor-κB (NF-κB) immunopositivity. Additionally, CBZ dose-dependently elevated the alanine aminotransferase, aspartate aminotransferase, alkaline phosphatase, urea, and creatinine serum levels and reduced the serum albumin levels. Furthermore, CBZ-induced apoptosis, as indicated by the observed Bax gene upregulation and Bcl-2 gene downregulation in both organs. All these changes may be related to oxidative stress, as indicated by the increase in malondialdehyde levels and the decrease in total antioxidant capacity. Our results demonstrate that CBZ-induced dose-and time-dependent hepatorenal damage through oxidative stress, which activated both the NF-κB signaling pathway and Bcl-based programmed cell death.
Imidacloprid (IMI) insecticide is rapidly metabolized
in mammals
and contributes to neurotoxicity via the blocking of nicotinic acetylcholine
receptors, as in insects. Origanum majorana retains its great antioxidant potential in both fresh and dry forms.
No data is available on the neuroprotective effect of this plant in
laboratory animals. In this context, aerial parts of O. majorana were used to prepare the essential oil
(OMO) and methanol extract (OME). The potential neuroprotective impact
of both OMO and OME against IMI-induced neurotoxicity in rats was
explored. Forty-two rats were divided into 6 groups, with 7 rats in
each one. Rats were daily administered the oral treatments: normal
saline, OMO, OME, IMI, IMI + OMO, and IMI + OME. Our results revealed
the identification of 55 components in O. majorana essential oil, most belonging to the oxygenated and hydrocarbon
monoterpenoid group. Moreover, 37 constituents were identified in
the methanol extract, mostly phenolics. The potent neurotoxic effect
of IMI on rats was confirmed by neurobehavioral and neuropathological
alterations and a reduction of both acetylcholine esterase (AchE)
activity and dopamine (DA), serotonin (5HT), and γ-aminobutyric
acid (GABA) levels in the brain. Exposure of rats to IMI elevates
the malondialdehyde (MDA) levels and reduces the antioxidant capacity.
IMI could upregulate the transcription levels of nuclear factor-κB
(NF-κB), interleukin-1 β (IL-1β), and tumor necrosis
factor (TNF-α) genes and express strong caspase-3 and inducible
nitric oxide synthase (iNOS) immunostaining in most examined brain
areas. On the other hand, rats coadministered OMO or OME with IMI
showed a marked improvement in all of the studied toxicological parameters.
In conclusion, cotreatment of O. majorana extracts with IMI can protect against IMI neurotoxicity via their
potent antioxidant, anti-inflammatory, and anti-apoptotic effects.
Thus, we recommend a daily intake of O. majorana to protect against insecticide’s oxidative stress-mediated
neuroinflammatory stress and apoptosis. The molecular docking study
of linalool, rosmarinic acid, γ-terpene, and terpene-4-ol justify
the observed normalization of the elevated iNOS and TNF-α levels
induced after exposure to IMI.
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